In a semiconductor device particularly including a phase change material, the reliability of the read-out operation is improved. In a read-out operation of a phase change memory, a bit line to be read out is precharged in advance with a sufficiently low voltage that can prevent the destructive read operation. In this state, after a word line is activated and a period in which the voltage is sufficiently discharged via a storage element which is in a low resistance state elapses (first read out), charge sharing is performed between the bit line and a read bit line of a sense amplifier which is precharged to a high voltage, and a read-out operation is performed again (second read out). Consequently, the read-out signal amount can be increased while suppressing the read current.
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1. A semiconductor device comprising:
a plurality of word lines;
a first bit line;
a sense amplifier;
a plurality of memory cells disposed at arbitrary intersecting points of said plurality of word lines and said first bit line;
a second bit line and a third bit line connected to said sense amplifier;
a first switch for providing a first potential to said first bit line;
a second switch for providing a second potential to said second bit line; and
a third switch for connecting said first bit line with said second bit line,
wherein, after said first switch is inactivated, any of said plurality of word lines is activated, and said third switch is activated.
10. A semiconductor device comprising:
a plurality of word lines;
a first bit line;
a second bit line;
a sense amplifier;
a plurality of memory cells disposed at arbitrary intersecting points of said plurality of word lines and said first and second bit lines;
a third bit line and a fourth bit line connected to said sense amplifier;
a first switch for providing a first potential to said first bit line;
a second switch for providing a second potential to said second bit line;
a third switch for providing a third potential to said third bit line;
a fourth switch for providing said third potential to said fourth bit line;
a fifth switch for connecting said first bit line with said third bit line; and
a sixth switch for connecting said second bit line with said fourth bit line,
wherein, after said first switch is activated and a first period elapses, inactivation of said first switch and activation of any of said plurality of word lines are performed, and after a second period elapses, said fifth and sixth switches are activated for a third period.
2. The semiconductor device according to
wherein said first potential is lower than said second potential.
3. The semiconductor device according to
wherein a third potential is provided to said third bit line, and
said third potential is lower than said second potential.
4. The semiconductor device according to
wherein said third potential is outputted by an internal power-supply step-down circuit.
5. The semiconductor device according to
a fourth bit line disposed in parallel to said first bit line;
a seventh switch for providing said second potential to said third bit line;
a fourth switch for providing a fourth potential to said fourth bit line; and
a fifth switch for connecting said fourth bit line with said third bit line,
wherein said second potential is higher than said first potential,
said fourth potential is lower than said first potential, and,
after said fourth and seventh switches are inactivated, said fifth switch is activated.
6. The semiconductor device according to
wherein each of said plurality of memory cells is comprised of a first MISFET and a variable resistive element,
a first terminal of said variable resistive element is connected to said first bit line,
a second terminal of said variable resistive element is connected to one of source/drain of said first MISFET,
a gate of said first MISFET is connected to any one of said plurality of word lines, and
the other of the source/drain of said first MISFET is connected to a common source line.
7. The semiconductor device according to
wherein a sixth switch for providing a fourth potential is disposed on said first bit line,
said fourth potential is provided to said common source line, and
said fourth potential is lower than said first and second potentials.
8. The semiconductor device according to
wherein each of said plurality of memory cells is comprised of a first MISFET and a variable resistive element,
a first terminal of said variable resistive element is connected to a common source line,
a second terminal of said variable resistive element is connected to one of source/drain of said first MISFET,
a gate of said first MISFET is connected to any one of said plurality of word lines, and
the other of the source/drain of said first MISFET is connected to said first bit line.
9. The semiconductor device according to
wherein a sixth switch for providing a fourth potential is disposed on said first bit line,
said fourth potential is provided to said common source line, and
said fourth potential is lower than said first and second potentials.
11. The semiconductor device according to
wherein a seventh switch for providing said second potential is connected to said first bit line, and
after said third period elapses, said fifth and sixth switches are inactivated, said sense amplifier is activated, and said second and seventh switches are activated.
12. The semiconductor device according to
wherein said first potential is higher than said second potential, and
said third potential is higher than said first potential.
13. The semiconductor device according to
wherein each of said plurality of memory cells is comprised of a variable resistive element and a first MISFET,
a first terminal of said variable resistive element is connected to said first bit line,
a second terminal of said variable resistive element is connected to one of source/drain of said first MISFET,
a gate of said first MISFET is connected to any one of said plurality of word lines, and
the other of the source/drain of said first MISFET is connected to a common source line.
14. The semiconductor device according to
wherein said second potential is provided to said common source line.
15. The semiconductor device according to
wherein each of said plurality of memory cells is comprised of a first MISFET and a variable resistive element,
a first terminal of said variable resistive element is connected to a common source line,
a second terminal of said variable resistive element is connected to one of source/drain of said first MISFET,
a gate of said first MISFET is connected to any one of said plurality of word lines, and
the other of the source/drain of said first MISFET is connected to said first bit line.
16. The semiconductor device according to
wherein said second potential is provided to said common source line.
17. The semiconductor device according to
a seventh switch for providing said second potential to said first bit line;
an eighth switch for providing said first potential to said second bit line;
a ninth switch for connecting said second bit line with said third bit line; and
a tenth switch for connecting said first bit line with said fourth bit line.
18. The semiconductor device according to
a fifth bit line disposed in parallel to said first bit line;
a sixth bit line disposed in parallel to said second bit line;
an eleventh switch for connecting said fifth bit line with said third bit line; and
a twelfth switch for connecting said sixth bit line with said third bit line.
19. The semiconductor device according to
a thirteenth switch for providing said first potential to said fifth bit line; and
a fourteenth switch for providing said first potential to said sixth bit line.
20. The semiconductor device according to
wherein said semiconductor device activates said second switch and said seventh switch during a waiting period.
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The present application claims priority from Japanese Patent Application No. JP 2004-374314 filed on Dec. 24, 2004,the content of which is hereby incorporated by reference into this application.
The present invention relates to a semiconductor device. More particularly, it relates to a technology effectively applied to a semiconductor device having an integrated memory circuit, a logic-embedded memory in which memory circuits and logic circuits are provided on one semiconductor substrate, or an analog circuit, each of which is formed by using a phase change material.
According to an examination by the inventor of the present invention, the followings are known as the technologies for a memory using a phase change material.
Phase change memories have been under development in order to produce high-speed and large-scale integrated non-volatile memories. A memory (phase change memory) employing resistive elements made of a phase change material is a non-volatile memory, in which a temperature change such as that shown in
As described above, the phase change element changes the phase state thereof by electrical pulses. In order to perform a reset, a large current has to flow for a short period so as to rapidly cool the element. On the other hand, in order to perform a set, a current smaller than that in the reset has to flow for a comparatively long time so as to slowly cool the element. Meanwhile, in a read-out operation, the speed of a voltage drop in a bit line is sensed by use of a read voltage which is sufficiently lower than the write voltages, thereby reading out a ‘0’ state or a ‘1’ state of the phase change memory.
As a read-out method of a phase change memory, for example, a technology that enables easy setting of a sense amplifier reference level by amplifying input signals to the sense amplifier by use of a charge-transfer type preamplifier is disclosed in “2004 IEEE International Solid-State Circuits Conference, Digest of Technical Papers”, pp. 40 to 41 (Non-Patent Document 1).
Incidentally, as a result of the examination by the inventor of the present invention for the technology of a memory using a phase change material described above, the following facts have been found.
In the phase change memory, currents are caused to flow in an element both in a read-out operation and a write operation. In the write operation, the phase state of an element is changed between an amorphous state (high resistance state) and a crystalline state (low resistance state) by Joule heat generated by causing a large current to flow through a resistor itself or an adjacently disposed heater.
On the other hand, in the read-out operation, since a current is caused to flow through the element or the adjacent heater, the data in the element may be destroyed by Joule heat generated by the current. Also, there is a possibility that, when a read current flows, a thermal disturbance larger than expected is generated due to the influence of, for example, fluctuations in the internal voltage, the outside temperature, and element variations, and the stored data in peripheral memory elements are destroyed. Therefore, it is a task to reduce the applied voltage in the read out as much as possible so as to reduce the current that flows through the element and the heater and to reduce the amount of generated heat.
The methods of detecting the low resistance state and the high resistance state include a current sensing method in which a certain voltage is applied to the element and the current that flows through the element is compared with a reference current to detect the states, and a voltage sensing method in which a capacitive load is charged or discharged via the memory element and the voltage value after a certain time is compared with a reference voltage to detect the states. Since the scale of a sense circuit is large in the current sensing method, the voltage sensing is more suitable for an operation in which a large number of bits are read out at a time. However, in the voltage sensing method, when the applied voltage in the read out is low, the difference between the reference voltage and the read voltage becomes small. Therefore, it is a task to generate a stable reference voltage.
Under such circumstances, for example, a method employing a charge-transfer type preamplifier is disclosed in the above mentioned Non-Patent Document 1.However, in the method described in Non-Patent Document 1,since it does not operates as the preamplifier in some cases unless the gate voltage of a pass-gate transistor constituting the charge-transfer amplifier is well adjusted, the amplitude of the sense amplifier input signal can not be increased.
The typical ones of the inventions disclosed in this application will be briefly described as follows.
A semiconductor device according to the present invention comprises: a plurality of word lines; a first bit line; a sense amplifier; a plurality of memory cells disposed at arbitrary intersecting points of the plurality of word lines and the first bit line; a second bit line and a third bit line connected to the sense amplifier; a first switch for providing a first potential to the first bit line; a second switch for providing a second potential to the second bit line; and a third switch for connecting the first bit line with the second bit line, wherein, after the first switch is inactivated, any of the plurality of word lines is activated, and the third switch is activated.
More specifically, in a read-out operation, first, the word line of the memory cell is raised in a state where the first bit line to which the memory cell is connected is precharged in advance to a first potential, thereby charging/discharging electric charge of the first bit line via the memory cell. Then, the first bit line is connected to the second bit line which has been precharged to the second potential in advance and is connected to one of the input nodes of the sense amplifier, thereby charging/discharging the first bit line again via the memory cell and obtaining an input signal of the sense amplifier from the second bit line having a potential equal to the first bit line.
When gradual charge/discharge is employed in the above-described manner for obtaining a desired voltage amplitude as an input signal of the sense amplifier, the amount of electric charge involved in one time of charge/discharge is reduced and the current and the voltage are reduced as a result of the reduction in the amount of electric charge, and therefore, heat generation of the memory cell can be suppressed. Consequently, a highly reliable read-out operation can be performed.
Also, a third bit line serving as a reference is connected to the other input node of the sense amplifier. For the signal inputted to this bit line, a third potential serving as a fixed voltage may be generated by use of, for example, an internal power-supply step-down circuit, or a fourth bit line which is disposed in parallel to the first bit line and is in an unselected state during the read out may be employed.
In the latter case, for example, the third bit line and the fourth bit line are connected to each other in a state where the third bit line is precharged to the second potential which is higher than the first potential similar to the second bit line, and the fourth bit line is precharged to a fourth potential which is lower than the first potential since it is in an unselected state. Accordingly, a signal at an approximately intermediate level between ‘H’ level signal and an ‘L’ level signal which are read out to the second bit line can be supplied to the third bit line as a reference. At this time, since the reference voltage is generated in the third bit line by a mechanism which is similar to that of the read out of the signal to the second bit line, a stable reference voltage with a high tolerance against noise due to the voltage variations and manufacturing variations can be generated.
In addition, the reason why the unselected fourth bit line is set to the fourth potential is to suppress the voltage application to the memory cells which are connected to the fourth bit line during a period such as a waiting period when read and write to the memory cells are not required. Therefore, not only the fourth bit line but also the bit lines connected to the memory cells are set to the fourth potential by use of switches except for the time of read, write, and others in which voltage application is required.
It should be noted that the above-described effects are particularly advantageous in the case where the storage elements of the memory cells are variable resistive elements of, for example, a chalcogenide material.
The effects obtained by typical aspects of the present invention will be briefly described below. Particularly in a semiconductor device including a phase change material, reliability of read-out operations is improved, and stable generation of a reference voltage can be realized.
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiment, and the repetitive description thereof will be omitted. Although not particularly limited, the circuit elements constituting functional blocks in the embodiments below are formed on a semiconductor substrate such as single crystal silicon by integrated circuit technologies of, for example, publicly known CMOS (complementary MOS transistor).
In the embodiments, a MOS (Metal oxide Semiconductor) transistor is employed as an example of MISFET (Metal Insulator Semiconductor Field Effect Transistor). In the drawings, symbols of arrows are added to the bodies of PMOS transistors so as to discriminate them from NMOS transistors. Although the connection of the potential of the substrate of the MOS transistors is not particularly illustrated in the drawings, no particular limitation is imposed on the connection method as long as the MOS transistors can be normally operated.
Also, unless otherwise stated, a low level of a signal is defined as ‘0’, and a high level thereof is defined as ‘1’. In the following description, a ‘0’ state corresponds to a case where a storage element is in a crystalline state and has a low resistance value, and a ‘1’ state corresponds to a case where the element is in an amorphous state and has a high resistance value. Alternatively, the ‘0’ state may correspond to the case where the element is in the amorphous state and has a high resistance value, and the ‘1’ state may correspond to the case where the element is in a crystalline state and has a low resistance value.
(First Embodiment)
Before describing details of the operation, circuit configurations for realizing the present read-out operation will be described below.
In this configuration example, in the sense amplifier block SAB, one line selected from four bit lines BL0, BL1, BL2, and BL3 by a bit line selection circuit BLSEL is connected to a sense amplifier circuit SA. The bit line selection circuit BLSEL selects one line from the four bit lines in accordance with an inputted address (not shown) and connects the selected bit line to a read bit line BLSA in a read-out operation and connects the line to a write bit line WBL in a write operation.
The sense amplifier circuit SA is a circuit which performs determination of ‘1’/‘0’ by comparing a minute signal read out to the bit line of the array with a reference level VREF, and outputs data to outside the array via a sense amplifier output node SAO (not shown in
The configuration example shown in
The memory array MA is divided into a plurality of the memory cell arrays MCA, and sub word drivers SWD, the sense amplifier blocks SAB, and cross areas XA are included between the memory cell arrays MCA. Although the memory array MA has a multi-divided configuration here, the multi-divided configuration is not always required. The cross areas XA are the parts where the sense amplifier blocks SAB and the sub word drivers SWD intersect, and circuits for driving the control signals of the sense amplifier blocks and the sub word drivers are mainly disposed.
The configuration example in
Also, as the configuration of the interior of the memory cell; the configuration in which the positions of the memory cell transistor MT and the storage element PCR of
In addition, an NMOS transistor is shown as the memory cell transistor MT herein. However, a PMOS transistor or a bipolar transistor is also available. However, in terms of large scale integration and process compatibility with peripheral circuits, a MOS transistor is desirable, and an NMOS transistor having a channel resistance in an on state smaller than that of a PMOS transistor is more preferable. Hereinafter, the configuration as shown in
In addition to those described above, the bit line selection circuit BLSEL is further provided with switches which are controlled by bit line equalize signals EQ0 to EQ3 so as to set the bit lines BL0 to BL3 in a waiting period to a predetermined voltage level, for example, a source line potential VS of the memory cells MC, precharge switches which are controlled by bit line precharge signals PCA0 to PCA3 so as to set the bit lines BL0 to BL3 to an initial voltage level VR of the read out, and a switch which is controlled by a sense amplifier precharge signal PCSA so as to precharge the read bit line BLSA in the sense amplifier to a predetermined voltage level VDL of the read out.
Herein, all of the four bit line precharge signals PCA0 to PCA3 may be the same control signal (method in which the four bit lines are controlled by one bit line precharge signal at one time), or each of them may be an individual signal that is controlled by a corresponding address signal. Employment of the individual signals is advantageous in that power consumption can be reduced because waste charging and discharging of read-out/write unselected bit lines can be prevented. On the other hand, employment of the same signal is advantageous in that high-speed operations and reduction in area by virtue of reduced drive circuits of the control signals can be realized because control for each address is not required. Also, similar to the above-described precharge signal, the bit line equalize signals EQ0 to EQ3 may be the same control signal or may be individual control signals corresponding to respective address signals. Advantages of such cases are the same as the above-described case of the bit line precharge signals.
The amplifier circuit AMP is activated by a sense amplifier activation signal SAE which is a gate signal of the amplifier circuit driving MOS transistor. In this amplifier circuit AMP, when the read bit line BLSA in the sense amplifier has a potential lower than the reference level VREF, ‘H’ is outputted to the sense amplifier output node SAO, and when the read bit line BLSA has a potential higher than the reference level VREF, ‘L’ is output to the sense amplifier output node SAO. As long as similar functions are provided, the circuit configuration of the amplifier circuit AMP is not limited to this circuit configuration.
When the reset voltage VWR is applied to the write bit line WBL, any of the bit lines BL0, BL1, . . . in the array is driven to the reset voltage VWR via the bit line selection circuit BLSEL, and a write current that is required for the reset operation is supplied to the storage element PCR of the memory cell MC. The period in which the write bit line WBL is being driven herein is defined by the period in which the reset enable signal WR is being driven to a low potential.
On the other hand, when the external input data DATAt is in a high potential state and the external input data DATAb is in a low potential state, an operation of setting the memory cell MC is performed, and a set voltage VWS is applied to the write bit line WBL. When the set voltage VWS is applied to the write bit line WBL, any of the bit lines BL0, BL1, . . . in the array is driven to the set voltage VWS via the bit line selection circuit BLSEL, and a write current required for the set operation flows through the storage element PCR of the memory cell MC. The period in which the write bit line WBL is being driven is defined by the period in which the set enable signal WS is being driven to a low potential, and the period of the set operation is longer than the period of the reset operation. Thereafter, in any of the operations, when the set/reset enable signals WS/WR are in a high potential state, the write bit line WBL is driven to a low potential (for example, to the source line potential VS), and the write operation is terminated.
Different from
At this time, when the external input data DATAt is in a low potential state and the external input data DATAb is in a high potential state, an operation of resetting the memory cell MC is performed, and a reset current flows through the write bit line WBL. The reset current is transferred to any of the bit lines BL0, BL1, . . . in the array via the write bit line WBL and the bit line selection circuit BLSEL, and flows through the storage element PCR of the memory cell MC. The period in which the write current is flowing through the write bit line WBL is defined by the period in which the reset enable signal WR is being driven to a low potential.
On the other hand, when the external input data DATAt is in a high potential state and the external input data DATAb is in a low potential state, an operation of setting the memory cell MC is performed, and a set current flows through the write bit line WBL. The set current is transferred to any of the bit lines BL0, BL1, . . . in the array via the write bit line WBL and the bit line selection circuit BLSEL, and flows through the storage element PCR of the memory cell MC. The period in which the write current is flowing through the write bit line WBL is defined by the period in which the set enable signal WS is being driven to a low potential, and the period of the set operation is longer than the period of the reset operation. Thereafter, in any of the operations, when the set/reset enable signals WS/WR are in a high potential state, the write bit line WBL is driven to a low potential (for example, to the source line potential VS), and the write operation is terminated.
The read-out operation of the phase change memory having such a configuration will be described in detail with reference to
When a read command READ is inputted from outside, in the memory cell array MCA corresponding to an address which is also inputted at the same time, the bit line equalize signal EQ0 for setting the bit line BL and the source line SL to an equal potential during a waiting period is inactivated by making a transition from a high potential state to a low potential state, and the bit line BL0 in the array attains a floating state. The unselected bit lines BL1, BL2, and BL3 maintain the potential VS of the source lines SL by maintaining the corresponding bit line equalize signals EQ1, EQ2, and EQ3 to a high potential, such that unnecessary voltage application with respect to the storage elements PCR in the memory cells MC is prevented so as to prevent erroneous rewriting.
Subsequently, the bit line precharge signal PCA0 is activated by making a transition from a low potential state to a high potential state, and the selected bit line BL0 is set to a read bit line level VR. The read bit line level VR is a voltage that is sufficiently low such that no rewrite operation is performed even when it is applied to the storage element PCR. At this time, the unselected bit lines BL1, BL2, and BL3 maintain a waiting-period bit line level (source line potential VS).
After the bit line BL0 is set to the read bit line level VR, the bit line precharge signal PCA0 is inactivated. Then, the word line WL corresponding to the address which has been inputted at the same time as the read command READ is activated by making a transition from a low potential state VWL to a high potential state VWH. When the word line WL is activated, the memory cell transistor MT of the memory cell MC is driven, and the read bit line level VR is applied to the storage element PCR.
At this time, when the storage element PCR is in a high resistance state, that is, when it is in an amorphous (non-crystalline) state in the case where the phase change element is used, the current that flows through the element is small. Therefore, the bit-line potential is little varied from the precharged read bit line level VR. In
After the word line WL is activated and a predetermined period elapses, the read bit line selection signal RSEL0 for connecting the bit line BL0 of the array with the sense amplifier is activated. Accordingly, the period of a second read out in
When the storage element PCR of the selected memory cell is in a low resistance state, the bit line level before charge sharing is the potential equal to the source-line potential VS, and when it is in a high resistance state, the level is the read bit line level VR. When charge sharing occurs at this point, the level becomes VDL×CSA/(CSA+CB) in the low resistance state and becomes VR′=(VDL×CSA+VR×CB)/(CSA+CB) in the high resistance state. Herein, CB denotes bit line capacity in the array, and CSA denotes capacity of the read bit line BLSA in the sense amplifier.
During this period, since the word line WL is always in an activated state, when the storage element PCR is in the low resistance state, the charge of the bit line BL0 is continuously drawn to the source line SL. Meanwhile, in the high resistance state, the level of the bit line BL0 increases. However, the level after the charge sharing is little varied and maintained because the current that flows through the storage element PCR is small. According to this read-out operation, by appropriately setting the reference level VREF, the read bit line BLSA in the sense amplifier is on the higher potential side than the reference level in the high resistance state (Reset), and is on the lower potential side than the reference level VREF in the low resistance state (Set).
Then, after time elapses until the bit line which reads out the storage element PCR in the low resistance state attains a potential approximately equal to the source potential, the read bit line selection signal RSEL0 attains an inactivated state, thereby separating the bit line BL in the array from the read bit line BLSA in the sense amplifier. Approximately at the same time with this, the equalize signal EQ for setting the bit line BL in the array to a waiting-period voltage attains an activated state, and the bit line BL in the array is set to the potential that is equal to the source-line potential VS. Then, the period of the second read out in
Meanwhile, in the sense amplifier, when the amplifier is activated by the sense amplifier activation signal SAE, the read bit line BLSA in the sense amplifier is compared with the reference level VREF, and the data corresponding to the stored content is outputted to the sense amplifier output node SAO. In this case, a high potential is outputted in the low resistance state, and a low potential is outputted in the high resistance state. Then, the word line WL transits to an inactivated state, and the read bit line BLSA in the sense amplifier is precharged to the array voltage VDL again by the sense amplifier precharge switch in the bit line selection circuit BLSEL.
When the above-described read-out method is employed, the read voltage applied to the bit line can be reduced, and the period in which a high read voltage is applied to the bit line can be shortened. Therefore, heat generation during a read-out period can be suppressed and destructive read operation such as erroneous writing can be prevented. In addition, thermal disturbance due to the read current can be prevented, Consequently, a highly reliable and stable read-out operation can be performed.
More specifically, if the present read-out method is not employed, in order to obtain a read-out signal having the amplitude of the voltage VR′, for example, the method is employed in which a read out is performed only by applying a voltage almost equal to the voltage VR′ to the bit line for the period in which the voltage is discharged in
Next, the write operation will be described.
When a write command WRIT is inputted from outside, the equalize signal EQ1 of the bit line BL1 corresponding to the address which has been inputted at the same time as the command transits to an inactivated state. At this point, when a read out is to be performed once, the operation similar to the above-described read-out operation is performed. Then, in a state where the selected bit line and unselected bit lines are precharged to the source-line potential VS, the word line WL is activated. Then, write data inputted from outside is transferred through the data buses DATA t/b.
The write driver WD in the sense amplifier circuit SA drives the write bit line WBL in accordance with the potentials of the data buses DATA t/b. When DATAt is in a high potential state and DATAb is in a low potential state, the set write voltage VWS is supplied to the bit line BL1 during the set time determined by the set enable signal WS. Meanwhile, when the data bus DATAt is in a low potential state and the data bus DATAb is in a high potential state, the reset write voltage VWR is supplied to the bit line BL1 during the reset time determined by the reset enable signal WR. The reset time is usually shorter than the set time and is, for example, about 10 ns to 100 ns. On the other hand, the set time is usually about 50 ns to 1 us.
Thereafter, when the reset enable signal WR and the set enable signal WS transit to an inactivated state (high potential state in this case), the write operation is terminated. Then, the bit line BL of the array is fixed to the source-line potential VS again by the bit-line equalize signal EQ. When successive write operations are not performed, at this point, the activated word line WL transits to an unselected state, thereby attaining a waiting state. The write operation may be an operation in which writing is performed only to the selected memory cell after once performing a read-out operation, or may be an operation in which writing is performed to the selected memory cell without any read-out operation.
Next, other configuration examples of above-described circuit blocks will be described.
Similar to the above-described case of
Similar to the above-described case of
That is, the present configuration example has a common sense amplifier configuration in which, when either one of the left and right memory cells MC is activated, the sense amplifier circuit SA of the sense amplifier block SAB which is disposed between the two memory cell arrays MCA is activated. When such a common sense amplifier configuration is employed, the part of the memory array MA can be readily composed by a multi-divided array on the chip as shown in
Moreover, the selection circuit BLSEL is further provided with the bit line equalize signals EQ0 and EQ1 and equalize switches controlled by these equalize signals for setting the bit lines BL0 and BL1 to a bit line waiting-period voltage, for example, to the potential VS equal to that of the source lines in a waiting period, the bit line precharge signals PCA0 and PCA1 and precharge switches for setting the bit lines BL0 and BL1 to a desired level, for example, to the read bit line level VR in a read-out period, and the sense amplifier precharge signal PCSA and a sense amplifier precharge switch for setting the read bit line BLSA in the sense amplifier to a desired read voltage VDL.
The read bit line level VR is lower than the sense amplifier precharge voltage VDL. In a read-out operation in the configuration example of
The present configuration example is suitable for an operation of reading out a large amount of data since the number of the bit lines that can be read out to the sense amplifiers at the same time is increased in comparison with the above-described configuration example of
FIG, 16 is a block diagram showing another configuration example of a main part of the phase change memory different from
When the configuration example of
(Second Embodiment)
In a second embodiment, a method of generating the reference level in a read-out period will be described with using the above-described configurations and operations. Characteristics of the present method are that the time in which a high voltage is applied during a read-out period is shortened while increasing the read-out signal amount by performing a read out in two steps similar to the above-described read-out operation, and a stable reference level is generated by outputting the reference level by charge sharing. First, circuit configurations for realizing the present read-out operation will be described.
A bit line selection circuit BLSEL2 and a sense amplifier circuit SA2 are disposed in the sense amplifier block SAB. The bit line selection circuit BLSEL2 selects one bit line from four bit lines BL0 to BL3 in accordance with an inputted address, connects the selected bit line to the read bit line BLSA in a read-out period, and connects the line to the write bit line WBL in a write period. Furthermore, different from the cases of
When the common sense amplifier configuration is employed as described above, the part of the memory array MA can be readily composed by a multi-divided array on the chip as shown in
Next, the configurations of the memory cell arrays MCA of
On the other hand, the configuration of the memory cell array MCA of
Moreover, the present configuration is further provided with reference selection signals DSEL0 to DSEL3 for connecting the bit lines BL0 to BL3 of the array to the reference bit line BLREF which is paired with the read bit line BLSA, reference selection switches which are controlled by the reference selection signals, and the sense amplifier precharge signal PCSA and a sense amplifier precharge switch for setting the reference bit line BLREF to a desired level (for example, VDL) in a read-out period similar to the above-described read bit line BLSA. In a read-out operation, the reference selection switches connect an unselected bit line in which no memory cell is activated to the reference bit line BLREF in the sense amplifier. Accordingly, in the read-out operation, a reference level is generated by charge sharing between the capacity of the bit line and the capacity of the reference bit line BLREF in the sense amplifier.
More specifically, in the read-out operation, complementary signals are read out to the read bit line BLSA and the reference bit line BLREF in the sense amplifier, and, after amplifying these signals in an amplifier circuit AMP2, the amplified signals are outputted to an input/output line IOt/b via an input/output gate unit IOG. Meanwhile, in a write operation, write data inputted from outside is once written to the read bit line BLSA and the reference bit line BLREF as complementary signals via the input/output line IOt/b and the input/output gate unit IOG. Then, by using the data, the write driver WD writes the data to the storage element PCR in the memory cell via the write bit line WBL and the bit line BL in the array.
As described above, in the present configuration example, the time when the input/output line IOt/b is being occupied can be shortened by once writing data to the paired bit lines BLSA/BLREF in the sense amplifier. Therefore, the operation cycle of the input/output line IOt/b can be shortened. The configuration of the write driver WD may be the configuration in which one of the data buses DATAt/DATAb in the configurations shown in
Next, the read-out operation of the phase change memory having above-described configurations will be described.
In
After the precharge, the word line WL corresponding to the address which has been inputted at the same time as the command is changed from an unselected state to a selected state. In accordance with this, the potential of the bit line BL0 changes depending on the resistance state of the storage element PCR of the memory cell. At this point, when the storage element PCR of the memory cell MC is in a high resistance state, a current does not flow via the memory cell MC. Therefore, the potential of the bit line BL0 is little varied and maintains the read bit line level VR. Meanwhile, when the storage element PCR of the memory cell MC is in a low resistance state, a current flows via the memory cell MC, and the potential of the bit line BL0 transits toward the potential VS of the source line. At this time, the reference bit line BL1 maintains the source line potential VS.
Then, the read bit line selection signal RSEL0 of the bit line BL0 and the reference bit line selection signal DSEL1 of the bit line BL1 are activated. Consequently, charge sharing occurs between the read bit line BLSA in the sense amplifier and the bit line BL0 in the array, and when the storage element PCR is in the low resistance state, the voltage of the bit line BL0 becomes VDL×CSA/(CSA+CB), and when it is in the high resistance state, the voltage becomes VR′=(VDL×CSA+VR×CB)/(CSA+CB). Herein, CSA denotes the capacity of the read bit line BLSA, and CB denotes the capacity of the bit line BL0 in the array. Meanwhile, the reference bit line BL1 shares the charge with the reference bit line BLREF in the sense amplifier, and it transits to VDL×CSA/(CSA+CB) if the capacity of the reference bit line BLREF is equal to the capacity of the read bit line BLSA.
Thereafter, since the word line is still in the selected state, a read current flows through the memory cell which is in the low resistance state. Consequently, the potential of the selected bit line BL0 in the low resistance state transits again toward the source-line potential VS. Meanwhile, when the memory cell is in the high resistance state, the bit line potential VR′ after the charge sharing is maintained. Also, the bit line BL1 serving as a reference and the reference bit line BLREF in the sense amplifier maintain the level after the charge sharing, that is, VDL×CSA/(CSA+CB). As a result, the potential of the reference bit line BLREF, that is, VDL×CSA/(CSA+CB) is a level which is determined by a structural parameter. Also, it is between the bit line potential VS of the low resistance state and the bit line potential VR′ of the high resistance state, and it can be employed as a reference potential of the sense amplifier.
Furthermore, while the voltage applied in the low resistance state in the read-period is at most the read bit line level VR, a large read-out signal amount VR′=(VDL×CSA+VR×CB)/(CSA+CB) can be obtained. In other words, a large read-out signal amount can be ensured while keeping a small read current in the read-out operation. Furthermore, there is an advantage that, since the reference level is generated by use of the unselected bit line, the stable low-voltage reference level which is not readily influenced by the internal voltage variations can be generated. Thus, a highly reliable read-out operation can be performed.
When minute signals are read out to the bit line pair BLSA/BLREF in the sense amplifier, the read bit line selection signal RSEL0 and the reference bit line selection signal DSEL1 transit from the activated state to an unselected state. Consequently, the read bit line BLSA and the reference bit line BLREF are separated from the bit lines BL0 and BL1 in the array. When each of the bit lines is separated, the equalize signals EQ0 and EQ1 are activated, and the bit lines BL0 and BL1 in the array are set to the source-line level VS. Accordingly, no voltage is applied to the storage elements PCR, and data destruction can be prevented.
Approximately at the same time with this, the sense amplifier activation signal SAE is activated so as to amplify the minute signals between the bit line pair BLSA/BLREF in the sense amplifier to the bit line amplitude voltage VDL by the amplifier circuit AMP2 of the sense amplifier circuit SA2. Thereafter, by activating a column selection signal YS corresponding to the inputted address from the unselected level VSS to a selected level VCL, the input/output gate unit IOG is activated and the data read out from the memory cell MC is outputted to the input/output line IOt/b.
When output of the data is completed, the activated word line WL transits from the high potential state VWH which is a selected state to the unselected level VWL. Approximately at the same time with this, the sense amplifier activation signal SAE becomes an unselected state, and the bit line pair BLSA/BLREF in the sense amplifier is precharged to the array voltage VDL and attains a waiting state when the sense amplifier precharge signals PCSA are activated. At this time, all of the bit lines in the array are precharged to the source-line potential VS, and no voltage is applied to the storage element PCR and between the source/drain of the memory cell transistor MT. Thus, since no disturbance current flows, data destruction can be prevented.
Advantages of the semiconductor device according to the second embodiment will be described. In this embodiment, similar to the above-described first embodiment, while preventing the destructive read operation by reducing the voltage applied in the read out, a large read-out signal can be ensured in comparison with the read-out applied voltage by performing the read out in two separate steps with low voltages. Furthermore, in the present embodiment, since the low-voltage reference level is generated by utilizing an unselected read bit line, a stable low-voltage reference level can be generated without being affected by the internal operation voltage variation.
In the foregoing, the invention made by the inventor of the present invention has been concretely described based on the embodiments. However, it is needless to say that the present invention is not limited to the foregoing embodiments and various modifications and alterations can be made within the scope of the present invention.
The present invention is desired to be applied to semiconductor devices employing processing technologies of 180 nm or less in which rewrite currents of phase change elements can be reduced. Even in earlier process generations, similar effects can be obtained by reducing the contact areas to the phase change elements. In addition, it goes without saying that the present invention can be applied to further miniaturized generations. Moreover, as an operating voltage, the external power supply voltage VCC is desirably 2.5 V, 1.8 V, 1.5 V, or lower. When the voltage is reduced, since the power consumption is suppressed and the voltage applied to the device is reduced, reliability can be improved.
The voltage of 0 V or lower is suitable as the unselected level VWL of the word lines. When it is 0 V, no particular power supply circuit is required, and the chip area can be reduced. In addition, when it is a negative voltage, even when the threshold value of the memory cell transistors is reduced in order to improve the current driving force, the sub-threshold current in a waiting period can be reduced. As a result, it is possible to achieve the reduction in power consumption, and moreover, the reduction in the current flowing through the phase change elements in an unselected period. Furthermore, disturbance of unselected read/write memory cells can be suppressed, and data reliability and film reliability can be improved.
The word line selection level VWH is desirably equal to an external power supply voltage such as 2.5 V, 1.8 V, or 1.5 V. Alternatively, the voltage equal to that of a peripheral circuit power supply may be employed. Also, in order to ensure the current driving force of the memory cell transistor, a high voltage such as 2.0 V or 2.5 V may be employed by use of an internal step-up power supply. When the source-line level VS is equal to the ground level VSS, no extra power supply circuit is required, and the area can be reduced. The ground level VSS is 0 V. The peripheral circuit voltage VCL and the array voltage VDL are desirably about 1.0 V to 1.8 V. When the array voltage is a voltage lower than the peripheral circuit voltage, there is an advantage that power consumption can be reduced. Within this scope, peripheral transistors produced by normal CMOS processes can be utilized, and processes typical for memory cells are not required, and processes can be simplified.
The reset write voltage VWR among write voltages is desirably equal to the peripheral circuit voltage or equal to the word line selection level VWH. When a high voltage is employed, a large current can be ensured even in small memory transistors, and reduction in area can be realized. The set write voltage is desirably equal to or lower than the peripheral circuit voltage VCL. When a low voltage is employed, the current at the time of write operation can he reduced in comparison with a reset operation, and erroneous reset operations can be prevented.
Also, the read bit line level VR is desirably a voltage that does not cause disturbance at the time of a read-out operation of the element, for example, about 0.2 V to 0.4 V. When the reference level VREF in the present invention is equal to the read bit line level VR, the power supply circuit can be shared, and the power supply noise in a read out can be cancelled out as in-phase noise. Furthermore, the present invention can be applied to a single unit of memory chip and to a logic-embedded memory.
The semiconductor device according to the present invention is a technology effectively applied to a semiconductor device having an integrated memory circuit, a logic-embedded memory in which memory circuits and logic circuits are provided on one semiconductor substrate, or an analog circuit, each of which is formed by using a phase change material.
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